/* FreeTDS - Library of routines accessing Sybase and Microsoft databases
 * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005  Brian Bruns
 * Copyright (C) 2010-2015  Frediano Ziglio
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library General Public
 * License as published by the Free Software Foundation; either
 * version 2 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Library General Public License for more details.
 *
 * You should have received a copy of the GNU Library General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */

#include <config.h>

#include <stdarg.h>
#include <stdio.h>

#include <freetds/time.h>

#include <assert.h>
#include <ctype.h>

#if HAVE_ERRNO_H
#include <errno.h>
#endif /* HAVE_ERRNO_H */

#if HAVE_STDLIB_H
#include <stdlib.h>
#endif /* HAVE_STDLIB_H */

#if HAVE_STRING_H
#include <string.h>
#endif /* HAVE_STRING_H */

#if HAVE_STRINGS_H
#include <strings.h>
#endif /* HAVE_STRINGS_H */

#include <freetds/tds.h>
#include <freetds/convert.h>
#include <freetds/bytes.h>
#include <freetds/replacements.h>

typedef unsigned short utf16_t;

struct tds_time
{
	int tm_year; /**< year (0=1900) */
	int tm_mon;  /**< month (0-11) */
	int tm_mday; /**< month day (1-31) */
	int tm_hour; /**< hours (0-23) */
	int tm_min;  /**< minutes (0-59) */
	int tm_sec;  /**< seconds (0-59) */
	int tm_ns;   /**< nanoseconds (0-999999999) */
};

static TDS_INT tds_convert_int(TDS_INT num, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_int1(const TDS_TINYINT * src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_int2(const TDS_SMALLINT * src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_uint2(const TDS_USMALLINT * src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_int4(const TDS_INT* src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_uint4(const TDS_UINT * src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_int8(const TDS_INT8 * src, int desttype, CONV_RESULT * cr);
static TDS_INT tds_convert_uint8(const TDS_UINT8 * src, int desttype, CONV_RESULT * cr);
static int string_to_datetime(const char *datestr, TDS_UINT len, int desttype, CONV_RESULT * cr);
static bool is_dd_mon_yyyy(char *t);
static int store_dd_mon_yyy_date(char *datestr, struct tds_time *t);
static const char *parse_numeric(const char *buf, const char *pend,
	bool * p_negative, size_t *p_digits, size_t *p_decimals);

#define test_alloc(x) {if ((x)==NULL) return TDS_CONVERT_NOMEM;}

/*
 * Macros for number checks.
 * They work for signed/unsigned integers and floating point values
 * (accounting for truncation of any fractional portions of the latter).
 */
#define IS_TINYINT(x) ( -1 < (x) && (x) < 0x100 )
#define IS_SMALLINT(x) ( -32769 < (x) && (x) < 32768 )
#define IS_USMALLINT(x) ( -1 < (x) && (x) < 65536 )

/*
 * Macros for integer number checks.
 * IS_UINT works for both integers and floating point values.
 *
 * f77: I don't write -2147483648, some compiler seem to have some problem 
 * with this constant although is a valid 32bit value
 */
#define TDS_INT_MIN (-2147483647-1)
#define TDS_INT_MAX 2147483647
#define INT_IS_INT(x) (TDS_INT_MIN <= (x) && (x) <= TDS_INT_MAX)
#define TDS_UINT_MAX 4294967295u
#define IS_UINT(x) (-1 < (TDS_INT8)(x) && (x) < (TDS_INT8) TDS_UINT_MAX + 1)
#define TDS_INT8_MIN (-(((TDS_INT8)1)<<62) -(((TDS_INT8)1)<<62))
#define TDS_INT8_MAX ((((TDS_INT8) 0x7fffffff) << 32) + (TDS_INT8) 0xffffffffu)

/*
 * Macros for floating point number checks.
 * To avoid possible loss of precision, use upper bounds for floating point
 * values and test MIN - (x) < 1 rather than MIN - 1 < (x) for signed
 * destination types.
 */
#define TDS_INT_UPPER_FLOAT 2147483648.0f
#define FLOAT_IS_INT(x) (TDS_INT_MIN - (x) < 1.0f && (x) < TDS_INT_UPPER_FLOAT)
#define TDS_INT8_MIN_FLOAT (-9223372036854775808.0f)
#define TDS_INT8_UPPER_FLOAT 9223372036854775808.0f
#define FLOAT_IS_INT8(x) (TDS_INT8_MIN_FLOAT - (x) < 1.0f && (x) < TDS_INT8_UPPER_FLOAT)
#define TDS_UINT8_UPPER 18446744073709551616.0f
#define FLOAT_IS_UINT8(x) (-1.0f < (x) && (x) < TDS_UINT8_UPPER)

#define TDS_ISDIGIT(c) ((c) >= '0' && (c) <= '9')

#define BIGDATETIME_BIAS 693961

/**
 * \ingroup libtds
 * \defgroup convert Conversion
 * Conversions between datatypes.  Supports, for example, dbconvert().  
 */

/**
 * \addtogroup convert
 * @{ 
 */

/**
 * convert a number in string to a TDSNUMERIC
 * @return sizeof(TDS_NUMERIC) on success, TDS_CONVERT_* failure code on failure 
 */
static int string_to_numeric(const char *instr, const char *pend, CONV_RESULT * cr);

/**
 * convert a zero terminated string to NUMERIC
 * @return sizeof(TDS_NUMERIC) on success, TDS_CONVERT_* failure code on failure 
 */
static int stringz_to_numeric(const char *instr, CONV_RESULT * cr);

static TDS_INT string_to_int(const char *buf, const char *pend, TDS_INT * res);
static TDS_INT string_to_int8(const char *buf, const char *pend, TDS_INT8 * res);
static TDS_INT string_to_uint8(const char *buf, const char *pend, TDS_UINT8 * res);
static TDS_INT string_to_float(const TDS_CHAR * src, TDS_UINT srclen, int desttype, CONV_RESULT * cr);

static int store_hour(const char *, const char *, struct tds_time *);
static int store_time(const char *, struct tds_time *);
static int store_yymmdd_date(const char *, struct tds_time *);
static int store_monthname(const char *, struct tds_time *);
static int store_numeric_date(const char *, struct tds_time *);
static int store_mday(const char *, struct tds_time *);
static int store_year(int, struct tds_time *);

/* static int days_this_year (int years); */
static bool is_timeformat(const char *);
static bool is_numeric(const char *);
static bool is_alphabetic(const char *);
static bool is_ampm(const char *);
#define is_monthname(s) (store_monthname(s, NULL) >= 0)
static bool is_numeric_dateformat(const char *);

#if 0
static TDS_UINT utf16len(const utf16_t * s);
static const char *tds_prtype(int token);
#endif

const char tds_hex_digits[] = "0123456789abcdef";

/**
 * Copy a terminated string to result and return len or TDS_CONVERT_NOMEM
 */
static TDS_INT
string_to_result(int desttype, const char *s, CONV_RESULT * cr)
{
	size_t len = strlen(s);

	if (desttype != TDS_CONVERT_CHAR) {
		cr->c = tds_new(TDS_CHAR, len + 1);
		test_alloc(cr->c);
		memcpy(cr->c, s, len + 1);
	} else {
		memcpy(cr->cc.c, s, len < cr->cc.len ? len : cr->cc.len);
	}
	return (TDS_INT)len;
}

/**
 * Copy binary data to to result and return len or TDS_CONVERT_NOMEM
 */
static TDS_INT
binary_to_result(int desttype, const void *data, size_t len, CONV_RESULT * cr)
{
	if (desttype != TDS_CONVERT_BINARY) {
		cr->ib = tds_new(TDS_CHAR, len);
		test_alloc(cr->ib);
		memcpy(cr->ib, data, len);
	} else {
		memcpy(cr->cb.ib, data, len < cr->cb.len ? len : cr->cb.len);
	}
	return (TDS_INT)len;
}

#define CASE_ALL_CHAR \
	SYBCHAR: case SYBVARCHAR: case SYBTEXT: case XSYBCHAR: case XSYBVARCHAR
#define CASE_ALL_BINARY \
	SYBBINARY: case SYBVARBINARY: case SYBIMAGE: case XSYBBINARY: case XSYBVARBINARY: \
	case SYBLONGBINARY: case TDS_CONVERT_BINARY

/* TODO implement me */
/*
static TDS_INT 
tds_convert_ntext(int srctype,TDS_CHAR *src,TDS_UINT srclen,
      int desttype, CONV_RESULT *cr)
{
      return TDS_CONVERT_NOAVAIL;
}
*/

static TDS_INT
tds_convert_binary(const TDS_UCHAR * src, TDS_INT srclen, int desttype, CONV_RESULT * cr)
{
	int cplen;
	int s;
	char *c;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
		cplen = srclen * 2;
		if ((TDS_UINT)cplen > cr->cc.len)
			cplen = cr->cc.len;

		c = cr->cc.c;
		for (s = 0; cplen >= 2; ++s, cplen -= 2) {
			*c++ = tds_hex_digits[src[s]>>4];
			*c++ = tds_hex_digits[src[s]&0xF];
		}
		if (cplen)
			*c = tds_hex_digits[src[s]>>4];
		return srclen * 2;

	case CASE_ALL_CHAR:

		/*
		 * NOTE: Do not prepend 0x to string.  
		 * The libraries all expect a bare string, without a 0x prefix. 
		 * Applications such as isql and query analyzer provide the "0x" prefix.
		 */

		/* 2 * source length + 1 for terminator */

		cr->c = tds_new(TDS_CHAR, (srclen * 2) + 1);
		test_alloc(cr->c);

		c = cr->c;

		for (s = 0; s < srclen; s++) {
			*c++ = tds_hex_digits[src[s]>>4];
			*c++ = tds_hex_digits[src[s]&0xF];
		}

		*c = '\0';
		return (srclen * 2);
		break;
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBUINT4:
	case SYBINT8:
	case SYBUINT8:
	case SYBMONEY4:
	case SYBMONEY:
	case SYBREAL:
	case SYBFLT8:
		cplen = tds_get_size_by_type(desttype);
		if (srclen >= cplen)
			srclen = cplen;
		memcpy(cr, src, srclen);
		memset(((char*) cr) + srclen, 0, cplen - srclen);
		return cplen;
		break;

		/* conversions not allowed */
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:

		/* TODO should we do some test for these types or work as ints ?? */
	case SYBDECIMAL:
	case SYBNUMERIC:
	case SYBBIT:
	case SYBBITN:

	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

TDS_INT
tds_char2hex(TDS_CHAR *dest, TDS_UINT destlen, const TDS_CHAR * src, TDS_UINT srclen)
{
	unsigned int i;
	unsigned char hex1, c = 0;

	/* if srclen if odd we must add a "0" before ... */
	i = 0;		/* number where to start converting */
	if (srclen & 1) {
		++srclen;
		i = 1;
		--src;
	}
	for (; i < srclen; ++i) {
		hex1 = src[i];

		if ('0' <= hex1 && hex1 <= '9')
			hex1 &= 0x0f;
		else {
			hex1 &= 0x20 ^ 0xff;	/* mask off 0x20 to ensure upper case */
			if ('A' <= hex1 && hex1 <= 'F') {
				hex1 -= ('A' - 10);
			} else {
				tdsdump_log(TDS_DBG_INFO1,
					    "error_handler:  attempt to convert data stopped by syntax error in source field \n");
				return TDS_CONVERT_SYNTAX;
			}
		}
		assert(hex1 < 0x10);

		if ((i/2u) >= destlen)
			continue;

		if (i & 1)
			dest[i / 2u] = c | hex1;
		else
			c = hex1 << 4;
	}
	return srclen / 2u;
}

static TDS_INT
tds_convert_char(const TDS_CHAR * src, TDS_UINT srclen, int desttype, CONV_RESULT * cr)
{
	unsigned int i;

	TDS_INT8 mymoney;
	char mynumber[28];

	TDS_INT tds_i;
	TDS_INT8 tds_i8;
	TDS_UINT8 tds_ui8;
	TDS_INT rc;

	bool negative;
	size_t digits, decimals;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
		memcpy(cr->cc.c, src, srclen < cr->cc.len ? srclen : cr->cc.len);
		return srclen;

	case CASE_ALL_CHAR:
		cr->c = tds_new(TDS_CHAR, srclen + 1);
		test_alloc(cr->c);
		memcpy(cr->c, src, srclen);
		cr->c[srclen] = 0;
		return srclen;
		break;

	case SYBINT1:
	case SYBUINT1:
		if ((rc = string_to_int(src, src + srclen, &tds_i)) < 0)
			return rc;
		if (!IS_TINYINT(tds_i))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = tds_i;
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		if ((rc = string_to_int(src, src + srclen, &tds_i)) < 0)
			return rc;
		if (!IS_SMALLINT(tds_i))
			return TDS_CONVERT_OVERFLOW;
		cr->si = tds_i;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		if ((rc = string_to_int(src, src + srclen, &tds_i)) < 0)
			return rc;
		if (!IS_USMALLINT(tds_i))
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) tds_i;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		if ((rc = string_to_int(src, src + srclen, &tds_i)) < 0)
			return rc;
		cr->i = tds_i;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		if ((rc = string_to_int8(src, src + srclen, &tds_i8)) < 0)
			return rc;
		if (!IS_UINT(tds_i8))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) tds_i8;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		if ((rc = string_to_int8(src, src + srclen, &tds_i8)) < 0)
			return rc;
		cr->bi = tds_i8;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		if ((rc = string_to_uint8(src, src + srclen, &tds_ui8)) < 0)
			return rc;
		cr->ubi = tds_ui8;
		return sizeof(TDS_UINT8);
		break;
	case SYBFLT8:
	case SYBREAL:
		return string_to_float(src, srclen, desttype, cr);
		break;
	case SYBBIT:
	case SYBBITN:
		if ((rc = string_to_int(src, src + srclen, &tds_i)) < 0)
			return rc;
		cr->ti = tds_i ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;
	case SYBMONEY:
	case SYBMONEY4:

		src = parse_numeric(src, src + srclen, &negative, &digits, &decimals);
		if (!src)
			return TDS_CONVERT_SYNTAX;
		if (digits > 18)
			return TDS_CONVERT_OVERFLOW;

		i = 0;
		if (negative)
			mynumber[i++] = '-';
		for (; digits; --digits)
			mynumber[i++] = *src++;
		src++;
		for (digits = 0; digits < 4 && digits < decimals; ++digits)
			mynumber[i++] = *src++;
		for (; digits < 4; ++digits)
			mynumber[i++] = '0';

		/* convert number and check for overflow */
		if (string_to_int8(mynumber, mynumber + i, &mymoney) < 0)
			return TDS_CONVERT_OVERFLOW;

		if (desttype == SYBMONEY) {
			cr->m.mny = mymoney;
			return sizeof(TDS_MONEY);
		} else {
			if (!INT_IS_INT(mymoney))
				return TDS_CONVERT_OVERFLOW;
			cr->m4.mny4 = (TDS_INT) mymoney;
			return sizeof(TDS_MONEY4);
		}
		break;
	case SYBDATETIME:
	case SYBDATETIME4:
	case SYBMSTIME:
	case SYBMSDATE:
	case SYBMSDATETIME2:
	case SYBMSDATETIMEOFFSET:
	case SYBTIME:
	case SYBDATE:
	case SYB5BIGTIME:
	case SYB5BIGDATETIME:
		return string_to_datetime(src, srclen, desttype, cr);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		return string_to_numeric(src, src + srclen, cr);
		break;
	case SYBUNIQUE:{
			unsigned n = 0;
			char c;

			/* 
			 * format:	 XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX 
			 * or 		{XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX} 
			 * or 		 XXXXXXXX-XXXX-XXXX-XXXXXXXXXXXXXXXX  
			 * or 		{XXXXXXXX-XXXX-XXXX-XXXXXXXXXXXXXXXX} 
			 * SQL seem to ignore the additional braces.
			 */
			if (srclen < (32 + 3))
				return TDS_CONVERT_SYNTAX;

			if (src[0] == '{') {
				TDS_UINT last = (src[8+1 + 4+1 + 4+1 + 4 + 1] == '-') ? 32+4+1 : 32+3+1;
				if (srclen <= last || src[last] != '}')
					return TDS_CONVERT_SYNTAX;
				++src;
			}

			/* 
			 * Test each character and get value.  
			 * sscanf works if the number terminates with less digits. 
			 */
			for (i = 0; i < 32 + 3; ++i) {
				c = src[i];
				switch (i) {
				case 8:
					if (c != '-')
						return TDS_CONVERT_SYNTAX;
					cr->u.Data1 = n;
					n = 0;
					break;
				case 8+1 + 4:
					if (c != '-')
						return TDS_CONVERT_SYNTAX;
					cr->u.Data2 = n;
					n = 0;
					break;
				case 8+1 + 4+1 + 4:
					if (c != '-')
						return TDS_CONVERT_SYNTAX;
					cr->u.Data3 = n;
					n = 0;
					break;
				case 8+1 + 4+1 + 4+1 + 4:
					/* skip last (optional) dash */
					if (c == '-') {
						if (--srclen < 32 + 3)
							return TDS_CONVERT_SYNTAX;
						c = (++src)[i];
					}
					/* fall through */
				default:
					n = n << 4;
					if (c >= '0' && c <= '9')
						n += c - '0';
					else {
						c &= 0x20 ^ 0xff;
						if (c >= 'A' && c <= 'F')
							n += c - ('A' - 10);
						else
							return TDS_CONVERT_SYNTAX;
					}
					if (i > (16 + 2) && !(i & 1)) {
						cr->u.Data4[(i >> 1) - 10] = n;
						n = 0;
					}
				}
			}
		}
		return sizeof(TDS_UNIQUE);
	default:
		return TDS_CONVERT_NOAVAIL;
		break;
	}			/* end switch */
}				/* tds_convert_char */

static TDS_INT
tds_convert_bit(const TDS_CHAR * src, int desttype, CONV_RESULT * cr)
{
	return tds_convert_int(src[0] ? 1 : 0, desttype, cr);
}

static TDS_INT
tds_convert_int1(const TDS_TINYINT * src, int desttype, CONV_RESULT * cr)
{
	return tds_convert_int(*src, desttype, cr);
}

static TDS_INT
tds_convert_int2(const TDS_SMALLINT * src, int desttype, CONV_RESULT * cr)
{
	return tds_convert_int(*src, desttype, cr);
}

static TDS_INT
tds_convert_uint2(const TDS_USMALLINT * src, int desttype, CONV_RESULT * cr)
{
	return tds_convert_int(*src, desttype, cr);
}

static TDS_INT
tds_convert_int4(const TDS_INT * src, int desttype, CONV_RESULT * cr)
{
	return tds_convert_int(*src, desttype, cr);
}

static TDS_INT
tds_convert_uint4(const TDS_UINT * src, int desttype, CONV_RESULT * cr)
{
	TDS_UINT8 num;

	num = *src;
	return tds_convert_uint8(&num, desttype, cr);
}

static TDS_INT
tds_convert_int_numeric(unsigned char scale,
	unsigned char sign, TDS_UINT num, CONV_RESULT * cr)
{
	unsigned char orig_prec = cr->n.precision, orig_scale = cr->n.scale;
	cr->n.precision = 10;
	cr->n.scale = scale;
	cr->n.array[0] = sign;
	cr->n.array[1] = 0;
	TDS_PUT_UA4BE(&(cr->n.array[2]), num);
	return tds_numeric_change_prec_scale(&(cr->n), orig_prec, orig_scale);
}

static TDS_INT
tds_convert_int8_numeric(unsigned char scale,
	unsigned char sign, TDS_UINT8 num, CONV_RESULT * cr)
{
	unsigned char orig_prec = cr->n.precision, orig_scale = cr->n.scale;
	cr->n.precision = 20;
	cr->n.scale = scale;
	cr->n.array[0] = sign;
	cr->n.array[1] = 0;
	TDS_PUT_UA4BE(&(cr->n.array[2]), (TDS_UINT) (num >> 32));
	TDS_PUT_UA4BE(&(cr->n.array[6]), (TDS_UINT) num);
	return tds_numeric_change_prec_scale(&(cr->n), orig_prec, orig_scale);
}

static TDS_INT
tds_convert_int(TDS_INT num, int desttype, CONV_RESULT * cr)
{
	TDS_CHAR tmp_str[16];

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(tmp_str, "%d", num);
		return string_to_result(desttype, tmp_str, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		if (!IS_TINYINT(num))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = (TDS_TINYINT) num;
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		if (!IS_SMALLINT(num))
			return TDS_CONVERT_OVERFLOW;
		cr->si = num;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		if (!IS_USMALLINT(num))
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) num;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		cr->i = num;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		if (num < 0)
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) num;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		cr->bi = num;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		if (num < 0)
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = (TDS_UINT8) num;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = num ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;
	case SYBFLT8:
		cr->f = num;
		return sizeof(TDS_FLOAT);
		break;
	case SYBREAL:
		cr->r = (TDS_REAL) num;
		return sizeof(TDS_REAL);
		break;
	case SYBMONEY4:
		if (num > 214748 || num < -214748)
			return TDS_CONVERT_OVERFLOW;
		cr->m4.mny4 = num * 10000;
		return sizeof(TDS_MONEY4);
		break;
	case SYBMONEY:
		cr->m.mny = (TDS_INT8) num *10000;

		return sizeof(TDS_MONEY);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		if (num < 0)
			return tds_convert_int_numeric(0, 1, (TDS_UINT) -num, cr);
		return tds_convert_int_numeric(0, 0, (TDS_UINT) num, cr);
		break;
		/* handled by upper layer */
	case CASE_ALL_BINARY:
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_int8(const TDS_INT8 *src, int desttype, CONV_RESULT * cr)
{
	TDS_INT8 buf;
	TDS_CHAR tmp_str[24];

	memcpy(&buf, src, sizeof(buf));
	if (INT_IS_INT(buf))
		return tds_convert_int((TDS_INT) buf, desttype, cr);

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(tmp_str, "%" PRId64, buf);
		return string_to_result(desttype, tmp_str, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBMONEY4:
		return TDS_CONVERT_OVERFLOW;
		break;
	case SYBUINT4:
		if (!IS_UINT(buf))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) buf;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		cr->bi = buf;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		if (buf < 0)
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = (TDS_UINT8) buf;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		/* this cannot be 0 as already tested above */
		cr->ti = 1;
		return sizeof(TDS_TINYINT);
		break;
	case SYBFLT8:
		cr->f = (TDS_FLOAT) buf;
		return sizeof(TDS_FLOAT);
		break;
	case SYBREAL:
		cr->r = (TDS_REAL) buf;
		return sizeof(TDS_REAL);
		break;
	case SYBMONEY:
		if (buf > (TDS_INT8_MAX / 10000) || buf < (TDS_INT8_MIN / 10000))
			return TDS_CONVERT_OVERFLOW;
		cr->m.mny = buf * 10000;
		return sizeof(TDS_MONEY);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		if (buf < 0)
			return tds_convert_int8_numeric(0, 1, -buf, cr);
		return tds_convert_int8_numeric(0, 0, buf, cr);
		break;
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_uint8(const TDS_UINT8 *src, int desttype, CONV_RESULT * cr)
{
	TDS_UINT8 buf;
	TDS_CHAR tmp_str[24];

	memcpy(&buf, src, sizeof(buf));
	/* INT_IS_INT does not work here due to unsigned/signed conversions */
	if (buf <= TDS_INT_MAX)
		return tds_convert_int((TDS_INT) buf, desttype, cr);

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(tmp_str, "%" PRIu64, buf);
		return string_to_result(desttype, tmp_str, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBMONEY4:
		return TDS_CONVERT_OVERFLOW;
		break;
	case SYBUINT4:
		if (!IS_UINT(buf))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) buf;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		if (buf > TDS_INT8_MAX)
			return TDS_CONVERT_OVERFLOW;
		cr->bi = (TDS_INT8) buf;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		cr->ubi = buf;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		/* this cannot be 0 as already tested above */
		cr->ti = 1;
		return sizeof(TDS_TINYINT);
		break;
	case SYBFLT8:
		cr->f = (TDS_FLOAT) buf;
		return sizeof(TDS_FLOAT);
		break;
	case SYBREAL:
		cr->r = (TDS_REAL) buf;
		return sizeof(TDS_REAL);
		break;
	case SYBMONEY:
		if (buf > (TDS_INT8_MAX / 10000))
			return TDS_CONVERT_OVERFLOW;
		cr->m.mny = buf * 10000;
		return sizeof(TDS_MONEY);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		return tds_convert_int8_numeric(0, 0, buf, cr);
		break;
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_numeric(const TDS_NUMERIC * src, int desttype, CONV_RESULT * cr)
{
	char tmpstr[MAXPRECISION];
	TDS_INT i, ret;
	TDS_INT8 bi;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		if (tds_numeric_to_string(src, tmpstr) < 0)
			return TDS_CONVERT_FAIL;
		return string_to_result(desttype, tmpstr, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 3, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[1] || (cr->n.array[0] && cr->n.array[2]))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = cr->n.array[2];
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 5, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		i = TDS_GET_UA2BE(&(cr->n.array[2]));
		if (cr->n.array[0])
			i = -i;
		if (((i >> 15) ^ cr->n.array[0]) & 1)
			return TDS_CONVERT_OVERFLOW;
		cr->si = (TDS_SMALLINT) i;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 5, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[0] || cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		i = TDS_GET_UA2BE(&(cr->n.array[2]));
		cr->usi = (TDS_USMALLINT) i;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 10, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		i = TDS_GET_UA4BE(&(cr->n.array[2]));
		if (cr->n.array[0])
			i = -i;
		if (((i >> 31) ^ cr->n.array[0]) & 1)
			return TDS_CONVERT_OVERFLOW;
		cr->i = i;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 10, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[0] || cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		i = TDS_GET_UA4BE(&(cr->n.array[2]));
		cr->ui = i;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 20, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		bi = TDS_GET_UA4BE(&(cr->n.array[2]));
		bi = (bi << 32) + TDS_GET_UA4BE(&(cr->n.array[6]));
		if (cr->n.array[0])
			bi = -bi;
		if (((bi >> 63) ^ cr->n.array[0]) & 1)
			return TDS_CONVERT_OVERFLOW;
		cr->bi = bi;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 20, 0);
		if (ret < 0)
			return ret;
		if (cr->n.array[0] || cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		bi = TDS_GET_UA4BE(&(cr->n.array[2]));
		bi = (bi << 32) + TDS_GET_UA4BE(&(cr->n.array[6]));
		cr->ubi = bi;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = 0;
		for (i = tds_numeric_bytes_per_prec[src->precision]; --i > 0;)
			if (src->array[i] != 0) {
				cr->ti = 1;
				break;
			}
		return sizeof(TDS_TINYINT);
		break;
	case SYBMONEY4:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 10, 4);
		if (ret < 0)
			return ret;
		if (cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		i = TDS_GET_UA4BE(&(cr->n.array[2]));
		if (cr->n.array[0])
			i = -i;
		if (((i >> 31) ^ cr->n.array[0]) & 1)
			return TDS_CONVERT_OVERFLOW;
		cr->m4.mny4 = i;
		return sizeof(TDS_MONEY4);
		break;
	case SYBMONEY:
		cr->n = *src;
		ret = tds_numeric_change_prec_scale(&(cr->n), 20, 4);
		if (ret < 0)
			return ret;
		if (cr->n.array[1])
			return TDS_CONVERT_OVERFLOW;
		bi = TDS_GET_UA4BE(&(cr->n.array[2]));
		bi = (bi << 32) + TDS_GET_UA4BE(&(cr->n.array[6]));
		if (cr->n.array[0])
			bi = -bi;
		if (((bi >> 63) ^ cr->n.array[0]) & 1)
			return TDS_CONVERT_OVERFLOW;
		cr->m.mny = bi;
		return sizeof(TDS_MONEY);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		{
			unsigned char prec = cr->n.precision, scale = cr->n.scale;
			cr->n = *src;
			return tds_numeric_change_prec_scale(&(cr->n), prec, scale);
		}
		break;
	case SYBFLT8:
		if (tds_numeric_to_string(src, tmpstr) < 0)
			return TDS_CONVERT_FAIL;
		cr->f = atof(tmpstr);
		return 8;
		break;
	case SYBREAL:
		if (tds_numeric_to_string(src, tmpstr) < 0)
			return TDS_CONVERT_FAIL;
		cr->r = (TDS_REAL) atof(tmpstr);
		return 4;
		break;
		/* TODO conversions to money */
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_money4(const TDSCONTEXT * tds_ctx, const TDS_MONEY4 * src, int desttype, CONV_RESULT * cr)
{
	TDS_MONEY4 mny;
	long dollars;
	char tmp_str[33];
	char *p;

	mny = *src;
	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR: {
		unsigned dollars;
		/*
		 * round to 2 decimal digits
		 * rounding with dollars = (mny.mny4 + 5000) /10000
		 * can give arithmetic overflow so I use
		 * dollars = (mny.mny4/50 + 1)/2 
		 */
		/* TODO round also all conversions to int and from money ?? */
		p = tmp_str;
		if (mny.mny4 < 0) {
			*p++ = '-';
			/* we use unsigned cause this cause arithmetic problem for -2^31*/
			dollars = -mny.mny4;
		} else {
			dollars = mny.mny4;
		}
		if (tds_ctx->money_use_2_digits) {
			/* print only 2 decimal digits as server does */
			dollars = (dollars + 50) / 100;
			sprintf(p, "%u.%02u", dollars / 100u, dollars % 100u);
		} else {
			sprintf(p, "%u.%04u", dollars / 10000u, dollars % 10000u);
		}
		return string_to_result(desttype, tmp_str, cr);
		} break;
	case SYBINT1:
	case SYBUINT1:
		dollars = mny.mny4 / 10000;
		if (!IS_TINYINT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = (TDS_TINYINT) dollars;
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		dollars = mny.mny4 / 10000;
		if (!IS_SMALLINT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->si = (TDS_SMALLINT) dollars;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		dollars = mny.mny4 / 10000;
		if (!IS_USMALLINT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) dollars;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		cr->i = mny.mny4 / 10000;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		dollars = mny.mny4 / 10000;
		if (!IS_UINT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = dollars;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		cr->bi = mny.mny4 / 10000;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		dollars = mny.mny4 / 10000;
		if (dollars < 0)
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = dollars;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = mny.mny4 ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;
	case SYBFLT8:
		cr->f = ((TDS_FLOAT) mny.mny4) / 10000.0;
		return sizeof(TDS_FLOAT);
		break;
	case SYBREAL:
		cr->r = (TDS_REAL) (mny.mny4 / 10000.0);
		return sizeof(TDS_REAL);
		break;
	case SYBMONEY:
		cr->m.mny = (TDS_INT8) mny.mny4;
		return sizeof(TDS_MONEY);
		break;
	case SYBMONEY4:
		cr->m4 = mny;
		return sizeof(TDS_MONEY4);
		break;
	case SYBDECIMAL:
	case SYBNUMERIC:
		if (mny.mny4 < 0)
			return tds_convert_int_numeric(4, 1, (TDS_UINT) -mny.mny4, cr);
		return tds_convert_int_numeric(4, 0, (TDS_UINT) mny.mny4, cr);
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		return TDS_CONVERT_NOAVAIL;
		break;
	}
	return TDS_CONVERT_FAIL;
}

static TDS_INT
tds_convert_money(const TDSCONTEXT * tds_ctx, const TDS_MONEY * src, int desttype, CONV_RESULT * cr)
{
	char *s;

	TDS_INT8 mymoney, dollars;
	char tmpstr[64];

	tdsdump_log(TDS_DBG_FUNC, "tds_convert_money()\n");
	mymoney = ((TDS_INT8) src->tdsoldmoney.mnyhigh << 32) | src->tdsoldmoney.mnylow;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		s = tds_money_to_string((const TDS_MONEY *) src, tmpstr, tds_ctx->money_use_2_digits);
		return string_to_result(desttype, s, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		if (mymoney <= -10000 || mymoney >= 256 * 10000)
			return TDS_CONVERT_OVERFLOW;
		/* TODO: round ?? */
		cr->ti = (TDS_TINYINT) (((TDS_INT) mymoney) / 10000);
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		if (mymoney <= -32769 * 10000 || mymoney >= 32768 * 10000)
			return TDS_CONVERT_OVERFLOW;
		cr->si = (TDS_SMALLINT) (((TDS_INT) mymoney) / 10000);
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		if (mymoney <= -1 * 10000 || mymoney >= 65536 * 10000)
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) (((TDS_INT) mymoney) / 10000);
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		dollars = mymoney / 10000;
		if (!INT_IS_INT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->i = (TDS_INT) dollars;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		dollars = mymoney / 10000;
		if (!IS_UINT(dollars))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) dollars;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		cr->bi = mymoney / 10000;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		dollars = mymoney / 10000;
		if (dollars < 0)
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = (TDS_UINT8) dollars;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = mymoney ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;
	case SYBFLT8:
		cr->f = ((TDS_FLOAT) mymoney) / 10000.0;
		return sizeof(TDS_FLOAT);
		break;
	case SYBREAL:
		cr->r = (TDS_REAL) (mymoney / 10000.0);
		return sizeof(TDS_REAL);
		break;
	case SYBMONEY4:
		if (!INT_IS_INT(mymoney))
			return TDS_CONVERT_OVERFLOW;
		cr->m4.mny4 = (TDS_INT) mymoney;
		return sizeof(TDS_MONEY4);
		break;
	case SYBMONEY:
		cr->m.mny = mymoney;
		return sizeof(TDS_MONEY);
		break;
	case SYBDECIMAL:
	case SYBNUMERIC:
		if (mymoney < 0)
			return tds_convert_int8_numeric(4, 1, -mymoney, cr);
		return tds_convert_int8_numeric(4, 0, mymoney, cr);
		break;
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_datetimeall(const TDSCONTEXT * tds_ctx, int srctype, const TDS_DATETIMEALL * dta, int desttype, CONV_RESULT * cr)
{
	char whole_date_string[64];
	TDSDATEREC when;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		tds_datecrack(srctype, dta, &when);
		tds_strftime(whole_date_string, sizeof(whole_date_string), tds_ctx->locale->date_fmt, &when, 
		             dta->time_prec);

		return string_to_result(desttype, whole_date_string, cr);
	case SYBDATETIME:
		cr->dt.dtdays = dta->date;
		cr->dt.dttime = (TDS_INT) ((dta->time * 3u + 50000u) / 100000u);
		return sizeof(TDS_DATETIME);
	case SYBDATETIME4:
		if (!IS_USMALLINT(dta->date))
			return TDS_CONVERT_OVERFLOW;
		cr->dt4.days = (TDS_USMALLINT) dta->date;
		cr->dt4.minutes = (TDS_USMALLINT) ((dta->time + 30u * 10000000u) / (60u * 10000000u));
		return sizeof(TDS_DATETIME4);
	case SYBMSDATETIMEOFFSET:
	case SYBMSDATE:
	case SYBMSTIME:
	case SYBMSDATETIME2:
		cr->dta = *dta;
		return sizeof(TDS_DATETIMEALL);
	case SYBDATE:
		cr->date = dta->date;
		return sizeof(TDS_DATE);
	case SYBTIME:
		cr->time = (TDS_INT) ((dta->time * 3u + 50000u) / 100000u);
		return sizeof(TDS_TIME);
	case SYB5BIGTIME:
		cr->bigtime = dta->time / 10u;
		return sizeof(TDS_UINT8);
	case SYB5BIGDATETIME:
		cr->bigtime = dta->time / 10u
			      + (dta->date + BIGDATETIME_BIAS) * ((TDS_UINT8) 86400u * 1000000u);
		return sizeof(TDS_UINT8);
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBBIT:
	case SYBBITN:
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBUINT4:
	case SYBINT8:
	case SYBUINT8:
	case SYBMONEY4:
	case SYBMONEY:
	case SYBNUMERIC:
	case SYBDECIMAL:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_datetime(const TDSCONTEXT * tds_ctx, const TDS_DATETIME * dt, int desttype, unsigned precision, CONV_RESULT * cr)
{
	char whole_date_string[64];
	TDSDATEREC when;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		tds_datecrack(SYBDATETIME, dt, &when);
		tds_strftime(whole_date_string, sizeof(whole_date_string), tds_ctx->locale->date_fmt, &when, 3);

		return string_to_result(desttype, whole_date_string, cr);
	case SYBDATETIME:
		cr->dt = *dt;
		return sizeof(TDS_DATETIME);
	case SYBDATETIME4:
		if (!IS_USMALLINT(dt->dtdays))
			return TDS_CONVERT_OVERFLOW;
		cr->dt4.days = dt->dtdays;
		cr->dt4.minutes = (dt->dttime / 300) / 60;
		return sizeof(TDS_DATETIME4);
	case SYBDATE:
		cr->date = dt->dtdays;
		return sizeof(TDS_DATE);
	case SYBTIME:
		cr->time = dt->dttime;
		return sizeof(TDS_TIME);
	case SYBMSDATETIMEOFFSET:
	case SYBMSDATE:
	case SYBMSTIME:
	case SYBMSDATETIME2:
		memset(&cr->dta, 0, sizeof(cr->dta));
		cr->dta.time_prec = precision;
		if (desttype == SYBMSDATETIMEOFFSET)
			cr->dta.has_offset = 1;
		if (desttype != SYBMSDATE) {
			cr->dta.has_time = 1;
			cr->dta.time_prec = 3;
			cr->dta.time = (((TDS_UINT8) dt->dttime) * 20 + 3) / 6 * 10000u;
		}
		if (desttype != SYBMSTIME) {
			cr->dta.has_date = 1;
			cr->dta.date = dt->dtdays;
		}
		return sizeof(TDS_DATETIMEALL);
	case SYB5BIGTIME:
		cr->bigtime = (((TDS_UINT8) dt->dttime) * 20u + 3u) / 6u * 1000u;
		return sizeof(TDS_BIGTIME);
	case SYB5BIGDATETIME:
		cr->bigdatetime = (((TDS_UINT8) dt->dttime) * 20u + 3u) / 6u * 1000u
				  + (dt->dtdays + BIGDATETIME_BIAS) * ((TDS_UINT8) 86400u * 1000000u);
		return sizeof(TDS_BIGDATETIME);
		/* conversions not allowed */
	case SYBUNIQUE:
	case SYBBIT:
	case SYBBITN:
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBUINT4:
	case SYBINT8:
	case SYBUINT8:
	case SYBMONEY4:
	case SYBMONEY:
	case SYBNUMERIC:
	case SYBDECIMAL:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_datetime4(const TDSCONTEXT * tds_ctx, const TDS_DATETIME4 * dt4, int desttype, CONV_RESULT * cr)
{
	TDS_DATETIME dt;

	if (desttype == SYBDATETIME4) {
		cr->dt4 = *dt4;
		return sizeof(TDS_DATETIME4);
	}

	/* convert to DATETIME and use tds_convert_datetime */
	dt.dtdays = dt4->days;
	dt.dttime = dt4->minutes * (60u * 300u);
	return tds_convert_datetime(tds_ctx, &dt, desttype, 0, cr);
}

static TDS_INT
tds_convert_time(const TDSCONTEXT * tds_ctx, const TDS_TIME * time, int desttype, CONV_RESULT * cr)
{
	TDS_DATETIME dt;

	if (desttype == SYBTIME) {
		cr->time = *time;
		return sizeof(TDS_TIME);
	}

	/* convert to DATETIME and use tds_convert_datetime */
	dt.dtdays = 0;
	dt.dttime = *time;
	return tds_convert_datetime(tds_ctx, &dt, desttype, 0, cr);
}

static TDS_INT
tds_convert_date(const TDSCONTEXT * tds_ctx, const TDS_DATE * date, int desttype, CONV_RESULT * cr)
{
	TDS_DATETIME dt;

	if (desttype == SYBDATE) {
		cr->date = *date;
		return sizeof(TDS_DATE);
	}

	/* convert to DATETIME and use tds_convert_datetime */
	dt.dtdays = *date;
	dt.dttime = 0;
	return tds_convert_datetime(tds_ctx, &dt, desttype, 0, cr);
}

static TDS_INT
tds_convert_bigtime(const TDSCONTEXT * tds_ctx, const TDS_BIGTIME * bigtime, int desttype, CONV_RESULT * cr)
{
	TDS_DATETIMEALL dta;

	if (desttype == SYB5BIGTIME) {
		cr->bigtime = *bigtime;
		return sizeof(TDS_BIGTIME);
	}

	/* convert to DATETIMEALL and use tds_convert_datetimeall */
	memset(&dta, 0, sizeof(dta));
	dta.time_prec = 6;
	dta.has_time = 1;
	dta.time = *bigtime % ((TDS_UINT8) 86400u * 1000000u) * 10u;
	return tds_convert_datetimeall(tds_ctx, SYBMSTIME, &dta, desttype, cr);
}

static TDS_INT
tds_convert_bigdatetime(const TDSCONTEXT * tds_ctx, const TDS_BIGDATETIME * bigdatetime, int desttype, CONV_RESULT * cr)
{
	TDS_DATETIMEALL dta;
	TDS_UINT8 bdt;

	if (desttype == SYB5BIGDATETIME) {
		cr->bigdatetime = *bigdatetime;
		return sizeof(TDS_BIGDATETIME);
	}

	/* convert to DATETIMEALL and use tds_convert_datetimeall */
	bdt = *bigdatetime;
	memset(&dta, 0, sizeof(dta));
	dta.time_prec = 6;
	dta.has_time = 1;
	dta.time = bdt % ((TDS_UINT8) 86400u * 1000000u) * 10u;
	bdt /= (TDS_UINT8) 86400u * 1000000u;
	dta.has_date = 1;
	dta.date = bdt - BIGDATETIME_BIAS;
	return tds_convert_datetimeall(tds_ctx, SYBMSDATETIME2, &dta, desttype, cr);
}


static TDS_INT
tds_convert_real(const TDS_REAL* src, int desttype, CONV_RESULT * cr)
{
	TDS_REAL the_value;

	/* FIXME how big should be this buffer ?? */
	char tmp_str[128];
	TDS_INT mymoney4;
	TDS_INT8 mymoney;

	the_value = *src;

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(tmp_str, "%.9g", the_value);
		return string_to_result(desttype, tmp_str, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		if (!IS_TINYINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = (TDS_TINYINT) the_value;
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		if (!IS_SMALLINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->si = (TDS_SMALLINT) the_value;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		if (!IS_USMALLINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) the_value;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		if (!FLOAT_IS_INT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->i = (TDS_INT) the_value;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		if (!IS_UINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) the_value;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		if (!FLOAT_IS_INT8(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->bi = (TDS_INT8) the_value;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		if (!FLOAT_IS_UINT8(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = (TDS_UINT8) the_value;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = the_value ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;

	case SYBFLT8:
		cr->f = the_value;
		return sizeof(TDS_FLOAT);
		break;

	case SYBREAL:
		cr->r = the_value;
		return sizeof(TDS_REAL);
		break;

	case SYBMONEY:
		if (the_value > (TDS_REAL) (TDS_INT8_MAX / 10000) || the_value < (TDS_REAL) (TDS_INT8_MIN / 10000))
			return TDS_CONVERT_OVERFLOW;
		mymoney = (TDS_INT8) (the_value * 10000);
		cr->m.mny = mymoney;
		return sizeof(TDS_MONEY);
		break;

	case SYBMONEY4:
		if (the_value > (TDS_REAL) (TDS_INT_MAX / 10000) || the_value < (TDS_REAL) (TDS_INT_MIN / 10000))
			return TDS_CONVERT_OVERFLOW;
		mymoney4 = (TDS_INT) (the_value * 10000);
		cr->m4.mny4 = mymoney4;
		return sizeof(TDS_MONEY4);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		sprintf(tmp_str, "%.*f", cr->n.scale, the_value);
		return stringz_to_numeric(tmp_str, cr);
		break;
		/* not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

/*
 * TODO: emit SYBECLPR errors: "Data conversion resulted in loss of precision".  
 * There are many places where this would be correct to do, but the test is tedious 
 * (convert e.g. 1.5 -> SYBINT and test if output == input) and we don't have a good, 
 * API-independent alternative to tds_client_msg().  Postponed until then.  
 */
static TDS_INT
tds_convert_flt8(const TDS_FLOAT* src, int desttype, CONV_RESULT * cr)
{
	TDS_FLOAT the_value;
	char tmp_str[25];

	memcpy(&the_value, src, 8);
	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(tmp_str, "%.17g", the_value);
		return string_to_result(desttype, tmp_str, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		if (!IS_TINYINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ti = (TDS_TINYINT) the_value;
		return sizeof(TDS_TINYINT);
		break;
	case SYBINT2:
		if (!IS_SMALLINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->si = (TDS_SMALLINT) the_value;
		return sizeof(TDS_SMALLINT);
		break;
	case SYBUINT2:
		if (!IS_USMALLINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->usi = (TDS_USMALLINT) the_value;
		return sizeof(TDS_USMALLINT);
		break;
	case SYBINT4:
		if (!FLOAT_IS_INT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->i = (TDS_INT) the_value;
		return sizeof(TDS_INT);
		break;
	case SYBUINT4:
		if (!IS_UINT(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ui = (TDS_UINT) the_value;
		return sizeof(TDS_UINT);
		break;
	case SYBINT8:
		if (!FLOAT_IS_INT8(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->bi = (TDS_INT8) the_value;
		return sizeof(TDS_INT8);
		break;
	case SYBUINT8:
		if (!FLOAT_IS_UINT8(the_value))
			return TDS_CONVERT_OVERFLOW;
		cr->ubi = (TDS_UINT8) the_value;
		return sizeof(TDS_UINT8);
		break;
	case SYBBIT:
	case SYBBITN:
		cr->ti = the_value ? 1 : 0;
		return sizeof(TDS_TINYINT);
		break;

	case SYBMONEY:
		if (the_value > (TDS_FLOAT) (TDS_INT8_MAX / 10000) || the_value < (TDS_FLOAT) (TDS_INT8_MIN / 10000))
			return TDS_CONVERT_OVERFLOW;
		cr->m.mny = (TDS_INT8) (the_value * 10000);

		return sizeof(TDS_MONEY);
		break;
	case SYBMONEY4:
		if (the_value > (TDS_FLOAT) (TDS_INT_MAX / 10000) || the_value < (TDS_FLOAT) (TDS_INT_MIN / 10000))
			return TDS_CONVERT_OVERFLOW;
		cr->m4.mny4 = (TDS_INT) (the_value * 10000);
		return sizeof(TDS_MONEY4);
		break;
	case SYBREAL:
		/* TODO check overflow */
		cr->r = (TDS_REAL)the_value;
		return sizeof(TDS_REAL);
		break;
	case SYBFLT8:
		cr->f = the_value;
		return sizeof(TDS_FLOAT);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		sprintf(tmp_str, "%.*f", cr->n.scale, the_value);
		return stringz_to_numeric(tmp_str, cr);
		break;
		/* not allowed */
	case SYBUNIQUE:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_unique(const TDS_CHAR * src, int desttype, CONV_RESULT * cr)
{
	/*
	 * raw data is equivalent to structure and always aligned, 
	 * so this cast is portable
	 */
	const TDS_UNIQUE *u = (const TDS_UNIQUE *) src;
	char buf[37];

	switch (desttype) {
	case TDS_CONVERT_CHAR:
	case CASE_ALL_CHAR:
		sprintf(buf, "%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X",
			(int) u->Data1, (int) u->Data2, (int) u->Data3,
			u->Data4[0], u->Data4[1], u->Data4[2], u->Data4[3], u->Data4[4], u->Data4[5], u->Data4[6], u->Data4[7]);
		return string_to_result(desttype, buf, cr);
		break;
	case SYBUNIQUE:
		/*
		 * Here we can copy raw to structure because we adjust
		 * byte order in tds_swap_datatype
		 */
		memcpy(&(cr->u), src, sizeof(TDS_UNIQUE));
		return sizeof(TDS_UNIQUE);
		break;
		/* do not warn for not convertible types */
	case SYBBIT:
	case SYBBITN:
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBUINT2:
	case SYBINT4:
	case SYBUINT4:
	case SYBINT8:
	case SYBUINT8:
	case SYBMONEY4:
	case SYBMONEY:
	case SYBDATETIME4:
	case SYBDATETIME:
	case SYBDATETIMN:
	case SYBREAL:
	case SYBFLT8:
	default:
		break;
	}
	return TDS_CONVERT_NOAVAIL;
}

static TDS_INT
tds_convert_to_binary(int srctype, const TDS_CHAR * src, TDS_UINT srclen, int desttype, CONV_RESULT * cr)
{
	size_t len;
	TDS_CHAR *ib;

	switch (srctype) {
	case CASE_ALL_BINARY:
		len = srclen;
		break;
	case SYBBIT:
	case SYBBITN:
	case SYBINT1:
	case SYBUINT1:
		len = 1;
		break;
	case SYBINT2:
	case SYBUINT2:
		len = 2;
		break;
	case SYBINT4:
	case SYBUINT4:
		len = 4;
		break;
	case SYBINT8:
	case SYBUINT8:
		len = sizeof(TDS_INT8);
		break;
	case SYBMONEY4:
		len = sizeof(TDS_MONEY4);
		break;
	case SYBMONEY:
		len = sizeof(TDS_MONEY);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		len = sizeof(TDS_NUMERIC);
		break;
	case SYBREAL:
		len = sizeof(TDS_REAL);
		break;
	case SYBFLT8:
		len = sizeof(TDS_FLOAT);
		break;
	case SYBDATETIME:
		len = sizeof(TDS_DATETIME);
		break;
	case SYBDATETIME4:
		len = sizeof(TDS_DATETIME4);
		break;
	case SYBTIME:
		len = sizeof(TDS_TIME);
		break;
	case SYBDATE:
		len = sizeof(TDS_DATE);
		break;
	case SYBMSTIME:
	case SYBMSDATE:
	case SYBMSDATETIME2:
	case SYBMSDATETIMEOFFSET:
		len = sizeof(TDS_DATETIMEALL);
		break;
	case SYB5BIGTIME:
		len = sizeof(TDS_BIGTIME);
		break;
	case SYB5BIGDATETIME:
		len = sizeof(TDS_BIGDATETIME);
		break;
	case SYBUNIQUE:
		len = sizeof(TDS_UNIQUE);
		break;
	case CASE_ALL_CHAR:

		/* skip leading "0x" or "0X" */
		if (srclen >= 2 && src[0] == '0' && (src[1] == 'x' || src[1] == 'X')) {
			src += 2;
			srclen -= 2;
		}

		/* ignore trailing blanks and nulls */
		/* FIXME is good to ignore null ?? */
		while (srclen > 0 && (src[srclen - 1] == ' ' || src[srclen - 1] == '\0'))
			--srclen;

		/* a binary string output will be half the length of */
		/* the string which represents it in hexadecimal     */

		ib = cr->cb.ib;
		if (desttype != TDS_CONVERT_BINARY) {
			cr->ib = tds_new(TDS_CHAR, (srclen + 2u) / 2u);
			test_alloc(cr->ib);
			ib = cr->ib;
		}
		return tds_char2hex(ib, desttype == TDS_CONVERT_BINARY ? cr->cb.len : 0xffffffffu, src, srclen);

	default:
		return TDS_CONVERT_NOAVAIL;
	}
	return binary_to_result(desttype, src, len, cr);
}

/**
 * tds_convert
 * convert a type to another.
 * If you convert to SYBDECIMAL/SYBNUMERIC you MUST initialize precision 
 * and scale of cr.
 * Do not expect strings to be zero terminated. Databases support zero inside
 * string. Using strlen may result on data loss or even a segmentation fault.
 * Instead, use memcpy to copy destination using length returned.
 * This function does not handle NULL, srclen should be >0.  Client libraries handle NULLs each in their own way. 
 * @param tds_ctx  context (used in conversion to data and to return messages)
 * @param srctype  type of source
 * @param src      pointer to source data to convert
 * @param srclen   length in bytes of source (not counting terminator or strings)
 * @param desttype type of destination
 * @param cr       structure to hold result
 * @return length of result or TDS_CONVERT_* failure code on failure. All TDS_CONVERT_* constants are <0.
 */
TDS_INT
tds_convert(const TDSCONTEXT *tds_ctx, int srctype, const void *src, TDS_UINT srclen, int desttype, CONV_RESULT *cr)
{
	TDS_INT length = 0;

	assert(srclen >= 0 && srclen <= 2147483647u);

	if (srctype == SYBVARIANT) {
		TDSVARIANT *v = (TDSVARIANT*) src;
		srctype = v->type;
		src = v->data;
		srclen = v->data_len;
	}

	switch (desttype) {
	case CASE_ALL_BINARY:
		return tds_convert_to_binary(srctype, src, srclen, desttype, cr);
	}

	switch (srctype) {
	case CASE_ALL_CHAR:
		length = tds_convert_char(src, srclen, desttype, cr);
		break;
	case SYBMONEY4:
		length = tds_convert_money4(tds_ctx, (const TDS_MONEY4 *) src, desttype, cr);
		break;
	case SYBMONEY:
		length = tds_convert_money(tds_ctx, (const TDS_MONEY *) src, desttype, cr);
		break;
	case SYBNUMERIC:
	case SYBDECIMAL:
		length = tds_convert_numeric((const TDS_NUMERIC *) src, desttype, cr);
		break;
	case SYBBIT:
	case SYBBITN:
		length = tds_convert_bit(src, desttype, cr);
		break;
	case SYBINT1:
	case SYBUINT1:
		length = tds_convert_int1((const TDS_TINYINT *) src, desttype, cr);
		break;
	case SYBINT2:
		length = tds_convert_int2((const TDS_SMALLINT *) src, desttype, cr);
		break;
	case SYBUINT2:
		length = tds_convert_uint2((const TDS_USMALLINT *) src, desttype, cr);
		break;
	case SYBINT4:
		length = tds_convert_int4((const TDS_INT *) src, desttype, cr);
		break;
	case SYBUINT4:
		length = tds_convert_uint4((const TDS_UINT *) src, desttype, cr);
		break;
	case SYBINT8:
		length = tds_convert_int8((const TDS_INT8 *) src, desttype, cr);
		break;
	case SYBUINT8:
		length = tds_convert_uint8((const TDS_UINT8 *) src, desttype, cr);
		break;
	case SYBREAL:
		length = tds_convert_real((const TDS_REAL *) src, desttype, cr);
		break;
	case SYBFLT8:
		length = tds_convert_flt8((const TDS_FLOAT *) src, desttype, cr);
		break;
	case SYBMSTIME:
	case SYBMSDATE:
	case SYBMSDATETIME2:
	case SYBMSDATETIMEOFFSET:
		length = tds_convert_datetimeall(tds_ctx, srctype, (const TDS_DATETIMEALL *) src, desttype, cr);
		break;
	case SYBDATETIME:
		length = tds_convert_datetime(tds_ctx, (const TDS_DATETIME* ) src, desttype, 3, cr);
		break;
	case SYBDATETIME4:
		length = tds_convert_datetime4(tds_ctx, (const TDS_DATETIME4* ) src, desttype, cr);
		break;
	case SYBTIME:
		length = tds_convert_time(tds_ctx, (const TDS_TIME *) src, desttype, cr);
		break;
	case SYBDATE:
		length = tds_convert_date(tds_ctx, (const TDS_DATE *) src, desttype, cr);
		break;
	case SYB5BIGTIME:
		length = tds_convert_bigtime(tds_ctx, (const TDS_BIGTIME *) src, desttype, cr);
		break;
	case SYB5BIGDATETIME:
		length = tds_convert_bigdatetime(tds_ctx, (const TDS_BIGDATETIME *) src, desttype, cr);
		break;
	case CASE_ALL_BINARY:
		length = tds_convert_binary((const TDS_UCHAR *) src, srclen, desttype, cr);
		break;
	case SYBUNIQUE:
		length = tds_convert_unique(src, desttype, cr);
		break;
	case SYBNVARCHAR:
	case SYBNTEXT:
	case SYBTABLETYPE:
	default:
		return TDS_CONVERT_NOAVAIL;
		break;
	}

/* fix MONEY case */
#if !defined(WORDS_BIGENDIAN)
	if (length > 0 && desttype == SYBMONEY) {
		cr->m.mny = ((TDS_UINT8) cr->m.mny) >> 32 | (cr->m.mny << 32);
	}
#endif
	return length;
}

static int
string_to_datetime(const char *instr, TDS_UINT len, int desttype, CONV_RESULT * cr)
{
	enum states {
		GOING_IN_BLIND,
		PUT_NUMERIC_IN_CONTEXT,
		DOING_ALPHABETIC_DATE
	};

	char *in;
	char *tok;
	char *lasts;
	char last_token[32];
	int monthdone = 0;
	int yeardone = 0;
	int mdaydone = 0;

	struct tds_time t;

	unsigned int dt_time;
	TDS_INT dt_days;
	int i;

	enum states current_state;

	memset(&t, '\0', sizeof(t));
	t.tm_mday = 1;

	in = tds_strndup(instr, len);
	test_alloc(in);

	tok = strtok_r(in, " ,", &lasts);

	current_state = GOING_IN_BLIND;

	while (tok != NULL) {

		tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: current_state = %d\n", current_state);
		switch (current_state) {
		case GOING_IN_BLIND:
			/* If we have no idea of current context, then if we have */
			/* encountered a purely alphabetic string, it MUST be an  */
			/* alphabetic month name or prefix...                     */

			if (is_alphabetic(tok)) {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: is_alphabetic\n");
				if (store_monthname(tok, &t) >= 0) {
					monthdone++;
					current_state = DOING_ALPHABETIC_DATE;
				} else {
					goto string_garbled;
				}
			}

			/* ...whereas if it is numeric, it could be a number of   */
			/* things...                                              */

			else if (is_numeric(tok)) {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: is_numeric\n");
				switch (strlen(tok)) {
					/* in this context a 4 character numeric can   */
					/* ONLY be the year part of an alphabetic date */

				case 4:
					store_year(atoi(tok), &t);
					yeardone++;
					current_state = DOING_ALPHABETIC_DATE;
					break;

					/* whereas these could be the hour part of a   */
					/* time specification ( 4 PM ) or the leading  */
					/* day part of an alphabetic date ( 15 Jan )   */

				case 2:
				case 1:
					strcpy(last_token, tok);
					current_state = PUT_NUMERIC_IN_CONTEXT;
					break;

					/* this must be a [YY]YYMMDD date             */

				case 6:
				case 8:
					if (store_yymmdd_date(tok, &t))
						current_state = GOING_IN_BLIND;
					else
						goto string_garbled;
					break;

					/* anything else is nonsense...               */

				default:
					goto string_garbled;
					break;
				}
			}

			/* it could be [M]M/[D]D/[YY]YY format              */

			else if (is_numeric_dateformat(tok)) {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: is_numeric_dateformat\n");
				store_numeric_date(tok, &t);
				current_state = GOING_IN_BLIND;
			} else if (is_dd_mon_yyyy(tok)) {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: is_dd_mon_yyyy\n");
				store_dd_mon_yyy_date(tok, &t);
				current_state = GOING_IN_BLIND;
			} else if (is_timeformat(tok)) {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: is_timeformat\n");
				store_time(tok, &t);
				current_state = GOING_IN_BLIND;
			} else {
				tdsdump_log(TDS_DBG_INFO1, "string_to_datetime: string_garbled\n");
				goto string_garbled;
			}

			break;	/* end of GOING_IN_BLIND */

		case DOING_ALPHABETIC_DATE:

			if (is_alphabetic(tok)) {
				if (!monthdone && store_monthname(tok, &t) >= 0) {
					monthdone++;
					if (monthdone && yeardone && mdaydone)
						current_state = GOING_IN_BLIND;
					else
						current_state = DOING_ALPHABETIC_DATE;
				} else {
					goto string_garbled;
				}
			} else if (is_numeric(tok)) {
				if (mdaydone && yeardone)
					goto string_garbled;
				else
					switch (strlen(tok)) {
					case 4:
						store_year(atoi(tok), &t);
						yeardone++;
						if (monthdone && yeardone && mdaydone)
							current_state = GOING_IN_BLIND;
						else
							current_state = DOING_ALPHABETIC_DATE;
						break;

					case 2:
					case 1:
						if (!mdaydone) {
							store_mday(tok, &t);

							mdaydone++;
							if (monthdone && yeardone && mdaydone)
								current_state = GOING_IN_BLIND;
							else
								current_state = DOING_ALPHABETIC_DATE;
						} else {
							store_year(atoi(tok), &t);
							yeardone++;
							if (monthdone && yeardone && mdaydone)
								current_state = GOING_IN_BLIND;
							else
								current_state = DOING_ALPHABETIC_DATE;
						}
						break;

					default:
						goto string_garbled;
					}
			} else {
				goto string_garbled;
			}

			break;	/* end of DOING_ALPHABETIC_DATE */

		case PUT_NUMERIC_IN_CONTEXT:

			if (is_alphabetic(tok)) {
				if (store_monthname(tok, &t) >= 0) {
					store_mday(last_token, &t);
					mdaydone++;
					monthdone++;
					if (monthdone && yeardone && mdaydone)
						current_state = GOING_IN_BLIND;
					else
						current_state = DOING_ALPHABETIC_DATE;
				} else if (is_ampm(tok)) {
					store_hour(last_token, tok, &t);
					current_state = GOING_IN_BLIND;
				} else {
					goto string_garbled;
				}
			} else if (is_numeric(tok)) {
				switch (strlen(tok)) {
				case 4:
				case 2:
					store_mday(last_token, &t);
					mdaydone++;
					store_year(atoi(tok), &t);
					yeardone++;

					if (monthdone && yeardone && mdaydone)
						current_state = GOING_IN_BLIND;
					else
						current_state = DOING_ALPHABETIC_DATE;
					break;

				default:
					goto string_garbled;
				}
			} else {
				goto string_garbled;
			}

			break;	/* end of PUT_NUMERIC_IN_CONTEXT */
		}

		tok = strtok_r(NULL, " ,", &lasts);
	}

	i = (t.tm_mon - 13) / 12;
	dt_days = 1461 * (t.tm_year + 1900 + i) / 4 +
		(367 * (t.tm_mon - 1 - 12 * i)) / 12 - (3 * ((t.tm_year + 2000 + i) / 100)) / 4 + t.tm_mday - 693932;

	free(in);

	if (desttype == SYBDATE) {
		cr->date = dt_days;
		return sizeof(TDS_DATE);
	}
	dt_time = t.tm_hour * 60 + t.tm_min;
	/* TODO check for overflow */
	if (desttype == SYBDATETIME4) {
		cr->dt4.days = dt_days;
		cr->dt4.minutes = dt_time;
		return sizeof(TDS_DATETIME4);
	}
	dt_time = dt_time * 60 + t.tm_sec;
	if (desttype == SYBDATETIME) {
		cr->dt.dtdays = dt_days;
		cr->dt.dttime = dt_time * 300 + (t.tm_ns / 1000000u * 300 + 150) / 1000;
		return sizeof(TDS_DATETIME);
	}
	if (desttype == SYBTIME) {
		cr->time = dt_time * 300 + (t.tm_ns / 1000000u * 300 + 150) / 1000;
		return sizeof(TDS_TIME);
	}
	if (desttype == SYB5BIGTIME) {
		cr->bigtime = dt_time * (TDS_UINT8) 1000000u + t.tm_ns / 1000u;
		return sizeof(TDS_BIGTIME);
	}
	if (desttype == SYB5BIGDATETIME) {
		cr->bigdatetime = (dt_days + BIGDATETIME_BIAS) * ((TDS_UINT8) 86400u * 1000000u)
				  + dt_time * (TDS_UINT8) 1000000u + t.tm_ns / 1000u;
		return sizeof(TDS_BIGDATETIME);
	}

	cr->dta.has_offset = 0;
	cr->dta.offset = 0;
	cr->dta.has_date = 1;
	cr->dta.date = dt_days;
	cr->dta.has_time = 1;
	cr->dta.time_prec = 7; /* TODO correct value */
	cr->dta.time = ((TDS_UINT8) dt_time) * 10000000u + t.tm_ns / 100u;
	return sizeof(TDS_DATETIMEALL);

string_garbled:
	tdsdump_log(TDS_DBG_INFO1,
		    "error_handler:  Attempt to convert data stopped by syntax error in source field \n");
	free(in);
	return TDS_CONVERT_SYNTAX;
}

static int
stringz_to_numeric(const char *instr, CONV_RESULT * cr)
{
	return string_to_numeric(instr, instr + strlen(instr), cr);
}

static int
string_to_numeric(const char *instr, const char *pend, CONV_RESULT * cr)
{
	char mynumber[(MAXPRECISION + 7) / 8 * 8 + 8];

	/* num packaged 8 digit, see below for detail */
	TDS_UINT packed_num[(MAXPRECISION + 7) / 8];

	char *ptr;

	int i = 0;
	int j = 0;
	int bytes;

	bool negative;
	size_t digits, decimals;

	/* FIXME: application can pass invalid value for precision and scale ?? */
	if (cr->n.precision > MAXPRECISION)
		return TDS_CONVERT_FAIL;

	if (cr->n.precision == 0)
		cr->n.precision = MAXPRECISION;	/* assume max precision */

	if (cr->n.scale > cr->n.precision)
		return TDS_CONVERT_FAIL;

	instr = parse_numeric(instr, pend, &negative, &digits, &decimals);
	if (!instr)
		return TDS_CONVERT_SYNTAX;

	cr->n.array[0] = negative ? 1 : 0;

	/* translate a number like 000ddddd.ffff to 00000000dddddffff00 */

	/* 
	 * Having disposed of any sign and leading blanks, 
	 * vet the digit string, counting places before and after 
	 * the decimal point.  Dispense with trailing blanks, if any.  
	 */

	ptr = mynumber;
	for (i = 0; i < 8; ++i)
		*ptr++ = '0';

	/* too many digits, error */
	if (cr->n.precision - cr->n.scale < digits)
		return TDS_CONVERT_OVERFLOW;

	/* copy digits before the dot */
	memcpy(ptr, instr, digits);
	ptr += digits;
	instr += digits + 1;

	/* copy digits after the dot */
	if (decimals > cr->n.scale)
		decimals = cr->n.scale;
	memcpy(ptr, instr, decimals);

	/* fill up decimal digits */
	memset(ptr + decimals, '0', cr->n.scale - decimals);
	ptr += cr->n.scale;

	/*
	 * Packaged number explanation: 
	 * We package 8 decimal digits in one number.  
	 * Because 10^8 = 5^8 * 2^8 = 5^8 * 256, dividing 10^8 by 256 leaves no remainder.
	 * We can thus split it into bytes in an optimized way.
	 */

	/* transform to packaged one */
	j = -1;
	ptr -= 8;
	do {
		TDS_UINT n = *ptr++;

		for (i = 1; i < 8; ++i)
			n = n * 10u + *ptr++;
		/* fix packet number and store */
		packed_num[++j] = n - ((TDS_UINT) '0' * 11111111lu);
		ptr -= 16;
	} while (ptr > mynumber);

	memset(cr->n.array + 1, 0, sizeof(cr->n.array) - 1);
	bytes = tds_numeric_bytes_per_prec[cr->n.precision];
	while (j > 0 && !packed_num[j])
		--j;

	for (;;) {
		bool is_zero = true;
		TDS_UINT carry = 0;
		i = j;
		if (!packed_num[j])
			--j;
		do {
			TDS_UINT tmp = packed_num[i];
			if (tmp)
				is_zero = false;

			/* divide for 256 for find another byte */
			/*
			 * carry * (25u*25u*25u*25u) = carry * 10^8 / 256u
			 * using unsigned number is just an optimization
			 * compiler can translate division to a shift and remainder 
			 * to a binary AND
			 */
			packed_num[i] = carry * (25u * 25u * 25u * 25u) + tmp / 256u;
			carry = tmp % 256u;
		} while(--i >= 0);
		if (is_zero)
			break;
		/*
		 * source number is limited to 38 decimal digit
		 * 10^39-1 < 2^128 (16 byte) so this cannot make an overflow
		 */
		cr->n.array[--bytes] = carry;
	}
	return sizeof(TDS_NUMERIC);
}

static bool
is_numeric_dateformat(const char *t)
{
	const char *instr;
	int slashes = 0;
	int hyphens = 0;
	int periods = 0;
	int digits = 0;

	for (instr = t; *instr; instr++) {
		if (!isdigit((unsigned char) *instr) && *instr != '/' && *instr != '-' && *instr != '.')
			return false;

		if (*instr == '/')
			slashes++;
		else if (*instr == '-')
			hyphens++;
		else if (*instr == '.')
			periods++;
		else
			digits++;

	}
	if (hyphens + slashes + periods != 2)
		return false;
	if (hyphens == 1 || slashes == 1 || periods == 1)
		return false;

	if (digits < 4 || digits > 8)
		return false;

	return true;

}

/* This function will check if an alphanumeric string */
/* holds a date in any of the following formats :     */
/*    DD-MON-YYYY */
/*    DD-MON-YY   */
/*    DDMONYY     */
/*    DDMONYYYY   */
static bool
is_dd_mon_yyyy(char *t)
{
	char *instr;
	char month[4];

	instr = t;

	if (!isdigit((unsigned char) *instr))
		return false;

	instr++;

	if (!isdigit((unsigned char) *instr))
		return false;

	instr++;

	if (*instr == '-') {
		instr++;

		strlcpy(month, instr, 4);

		if (!is_monthname(month))
			return false;

		instr += 3;

		if (*instr != '-')
			return false;

		instr++;
		if (!isdigit((unsigned char) *instr))
			return false;

		instr++;
		if (!isdigit((unsigned char) *instr))
			return false;

		instr++;

		if (*instr) {
			if (!isdigit((unsigned char) *instr))
				return false;

			instr++;
			if (!isdigit((unsigned char) *instr))
				return false;
		}

	} else {

		strlcpy(month, instr, 4);

		if (!is_monthname(month))
			return false;

		instr += 3;

		if (!isdigit((unsigned char) *instr))
			return false;

		instr++;
		if (!isdigit((unsigned char) *instr))
			return false;

		instr++;
		if (*instr) {
			if (!isdigit((unsigned char) *instr))
				return false;

			instr++;
			if (!isdigit((unsigned char) *instr))
				return false;
		}
	}

	return true;

}

static bool
is_ampm(const char *datestr)
{
	if (strcasecmp(datestr, "am") == 0)
		return true;

	if (strcasecmp(datestr, "pm") == 0)
		return true;

	return false;
}

static bool
is_alphabetic(const char *datestr)
{
	const char *s;

	for (s = datestr; *s; s++) {
		if (!isalpha((unsigned char) *s))
			return false;
	}
	return true;
}

static bool
is_numeric(const char *datestr)
{
	const char *s;

	for (s = datestr; *s; s++) {
		if (!isdigit((unsigned char) *s))
			return false;
	}
	return true;
}

static bool
is_timeformat(const char *datestr)
{
	const char *s;

	for (s = datestr; *s; s++) {
		if (!isdigit((unsigned char) *s) && *s != ':' && *s != '.')
			break;
	}
	if (*s)
		return is_ampm(s);

	return true;
}

static int
store_year(int year, struct tds_time *t)
{

	if (year < 0)
		return 0;

	if (year < 100) {
		if (year > 49)
			t->tm_year = year;
		else
			t->tm_year = 100 + year;
		return (1);
	}

	if (year < 1753)
		return (0);

	if (year <= 9999) {
		t->tm_year = year - 1900;
		return (1);
	}

	return (0);

}

static int
store_mday(const char *datestr, struct tds_time *t)
{
	int mday = atoi(datestr);

	if (mday > 0 && mday < 32) {
		t->tm_mday = mday;
		return 1;
	}
	return 0;
}

static int
store_numeric_date(const char *datestr, struct tds_time *t)
{
	int TDS_MONTH = 0;
	int TDS_DAY = 0;
	int TDS_YEAR = 0;

	int state;
	char last_char = 0;
	const char *s;
	int month = 0, year = 0, mday = 0;

	/* Its YYYY-MM-DD format */

	if (strlen(datestr) == 10 && *(datestr + 4) == '-' && *(datestr + 7) == '-') {

		TDS_YEAR = 0;
		TDS_MONTH = 1;
		TDS_DAY = 2;
		state = TDS_YEAR;

	}
	/* else we assume MDY */
	else {
		TDS_MONTH = 0;
		TDS_DAY = 1;
		TDS_YEAR = 2;
		state = TDS_MONTH;
	}
	for (s = datestr; *s; s++) {
		if (!isdigit((unsigned char) *s) && isdigit((unsigned char) last_char)) {
			state++;
		} else {
			if (state == TDS_MONTH)
				month = (month * 10) + (*s - '0');
			if (state == TDS_DAY)
				mday = (mday * 10) + (*s - '0');
			if (state == TDS_YEAR)
				year = (year * 10) + (*s - '0');
		}
		last_char = *s;
	}

	if (month > 0 && month < 13)
		t->tm_mon = month - 1;
	else
		return 0;
	if (mday > 0 && mday < 32)
		t->tm_mday = mday;
	else
		return 0;

	return store_year(year, t);

}

static int
store_dd_mon_yyy_date(char *datestr, struct tds_time *t)
{

	char dd[3];
	int mday;
	char mon[4];
	int year;

	tdsdump_log(TDS_DBG_INFO1, "store_dd_mon_yyy_date: %s\n", datestr);
	strlcpy(dd, datestr, 3);
	mday = atoi(dd);

	if (mday > 0 && mday < 32)
		t->tm_mday = mday;
	else
		return 0;

	if (datestr[2] == '-') {
		strlcpy(mon, &datestr[3], 4);

		if (store_monthname(mon, t) < 0) {
			tdsdump_log(TDS_DBG_INFO1, "store_dd_mon_yyy_date: store_monthname failed\n");
			return 0;
		}

		year = atoi(&datestr[7]);
		tdsdump_log(TDS_DBG_INFO1, "store_dd_mon_yyy_date: year %d\n", year);

		return store_year(year, t);
	} else {
		strlcpy(mon, &datestr[2], 4);

		if (store_monthname(mon, t) < 0) {
			tdsdump_log(TDS_DBG_INFO1, "store_dd_mon_yyy_date: store_monthname failed\n");
			return 0;
		}

		year = atoi(&datestr[5]);
		tdsdump_log(TDS_DBG_INFO1, "store_dd_mon_yyy_date: year %d\n", year);

		return store_year(year, t);
	}

}

/**
 * Test if a string is a month name and store correct month number
 * @return month number (0-11) or -1 if not match
 * @param datestr string to check
 * @param t       where to store month (if NULL no store is done)
 */
static int
store_monthname(const char *datestr, struct tds_time *t)
{
	int ret;

	tdsdump_log(TDS_DBG_INFO1, "store_monthname: %ld %s\n", (long) strlen(datestr), datestr);
	if (strlen(datestr) == 3) {
		if (strcasecmp(datestr, "jan") == 0)
			ret = 0;
		else if (strcasecmp(datestr, "feb") == 0)
			ret = 1;
		else if (strcasecmp(datestr, "mar") == 0)
			ret = 2;
		else if (strcasecmp(datestr, "apr") == 0)
			ret = 3;
		else if (strcasecmp(datestr, "may") == 0)
			ret = 4;
		else if (strcasecmp(datestr, "jun") == 0)
			ret = 5;
		else if (strcasecmp(datestr, "jul") == 0)
			ret = 6;
		else if (strcasecmp(datestr, "aug") == 0)
			ret = 7;
		else if (strcasecmp(datestr, "sep") == 0)
			ret = 8;
		else if (strcasecmp(datestr, "oct") == 0)
			ret = 9;
		else if (strcasecmp(datestr, "nov") == 0)
			ret = 10;
		else if (strcasecmp(datestr, "dec") == 0)
			ret = 11;
		else
			return -1;
	} else {
		if (strcasecmp(datestr, "january") == 0)
			ret = 0;
		else if (strcasecmp(datestr, "february") == 0)
			ret = 1;
		else if (strcasecmp(datestr, "march") == 0)
			ret = 2;
		else if (strcasecmp(datestr, "april") == 0)
			ret = 3;
		else if (strcasecmp(datestr, "june") == 0)
			ret = 5;
		else if (strcasecmp(datestr, "july") == 0)
			ret = 6;
		else if (strcasecmp(datestr, "august") == 0)
			ret = 7;
		else if (strcasecmp(datestr, "september") == 0)
			ret = 8;
		else if (strcasecmp(datestr, "october") == 0)
			ret = 9;
		else if (strcasecmp(datestr, "november") == 0)
			ret = 10;
		else if (strcasecmp(datestr, "december") == 0)
			ret = 11;
		else
			return -1;
	}
	if (t)
		t->tm_mon = ret;
	return ret;
}

static int
store_yymmdd_date(const char *datestr, struct tds_time *t)
{
	int month = 0, year = 0, mday = 0;

	int wholedate;

	wholedate = atoi(datestr);

	year = wholedate / 10000;
	month = (wholedate - (year * 10000)) / 100;
	mday = (wholedate - (year * 10000) - (month * 100));

	if (month > 0 && month < 13)
		t->tm_mon = month - 1;
	else
		return 0;
	if (mday > 0 && mday < 32)
		t->tm_mday = mday;
	else
		return 0;

	return (store_year(year, t));

}

static int
store_time(const char *datestr, struct tds_time *t)
{
	enum
	{ TDS_HOURS,
		TDS_MINUTES,
		TDS_SECONDS,
		TDS_FRACTIONS
	};

	int state = TDS_HOURS;
	char last_sep = '\0';
	const char *s;
	unsigned int hours = 0, minutes = 0, seconds = 0, nanosecs = 0;
	int ret = 1;
	unsigned ns_div = 1;

	for (s = datestr; *s && strchr("apmAPM", (int) *s) == NULL; s++) {
		if (*s == ':' || *s == '.') {
			last_sep = *s;
			state++;
		} else {
			if (*s < '0' || *s > '9')
				ret = 0;
			switch (state) {
			case TDS_HOURS:
				hours = (hours * 10u) + (*s - '0');
				break;
			case TDS_MINUTES:
				minutes = (minutes * 10u) + (*s - '0');
				break;
			case TDS_SECONDS:
				seconds = (seconds * 10u) + (*s - '0');
				break;
			case TDS_FRACTIONS:
				if (ns_div < 1000000000u) {
					nanosecs = (nanosecs * 10u) + (*s - '0');
					ns_div *= 10;
				}
				break;
			}
		}
	}
	if (*s) {
		if (strcasecmp(s, "am") == 0) {
			if (hours == 12)
				hours = 0;

			t->tm_hour = hours;
		}
		if (strcasecmp(s, "pm") == 0) {
			if (hours == 0)
				ret = 0;
			if (hours > 0u && hours < 12u)
				t->tm_hour = hours + 12;
			else
				t->tm_hour = hours;
		}
	} else {
		if (hours < 24u)
			t->tm_hour = hours;
		else
			ret = 0;
	}
	if (minutes < 60u)
		t->tm_min = minutes;
	else
		ret = 0;
	if (seconds < 60u)
		t->tm_sec = seconds;
	else
		ret = 0;
	tdsdump_log(TDS_DBG_FUNC, "store_time() nanosecs = %d\n", nanosecs);
	if (nanosecs) {
		if (nanosecs < ns_div && last_sep == '.')
			t->tm_ns = nanosecs * (1000000000u / ns_div);
		else if (nanosecs < 1000u)
			t->tm_ns = nanosecs * 1000000u;
		else
			ret = 0;
	}

	return (ret);
}

static int
store_hour(const char *hour, const char *ampm, struct tds_time *t)
{
	int ret = 1;
	int hours;

	hours = atoi(hour);

	if (hours >= 0 && hours < 24) {
		if (strcasecmp(ampm, "am") == 0) {
			if (hours == 12)
				hours = 0;

			t->tm_hour = hours;
		}
		if (strcasecmp(ampm, "pm") == 0) {
			if (hours == 0)
				ret = 0;
			if (hours > 0 && hours < 12)
				t->tm_hour = hours + 12;
			else
				t->tm_hour = hours;
		}
	}
	return ret;
}

/**
 * Get same type but nullable
 * @param srctype type requires
 * @return nullable type
 */
TDS_SERVER_TYPE
tds_get_null_type(TDS_SERVER_TYPE srctype)
{

	switch (srctype) {
	case SYBCHAR:
		return SYBVARCHAR;
		break;
	case SYBINT1:
	case SYBUINT1:
	case SYBINT2:
	case SYBINT4:
	case SYBINT8:
	/* TODO sure ?? */
	case SYBUINT2:
	case SYBUINT4:
	case SYBUINT8:
		return SYBINTN;
		break;
	case SYBREAL:
	case SYBFLT8:
		return SYBFLTN;
		break;
	case SYBDATETIME:
	case SYBDATETIME4:
		return SYBDATETIMN;
		break;
	case SYBBIT:
		return SYBBITN;
		break;
	case SYBMONEY:
	case SYBMONEY4:
		return SYBMONEYN;
		break;
	case SYBTIME:
		return SYBTIMEN;
		break;
	case SYBDATE:
		return SYBDATEN;
		break;
	default:
		break;
	}
	return srctype;
}

static void
two_digit(char *out, int num)
{
	if (num < 1)
		num = 1;
	if (num > 31)
		num = 31;
	out[0] = num < 10 ? ' ' : num/10 + '0';
	out[1] = num%10 + '0';
}

/**
 * format a date string according to an "extended" strftime(3) formatting definition.
 * @param buf     output buffer
 * @param maxsize size of buffer in bytes (space include terminator)
 * @param format  format string passed to strftime(3), except that %z represents fraction of seconds.
 * @param dr      date to convert
 * @param prec    second fraction precision (0-7).
 * @return length of string returned, 0 for error
 */
size_t
tds_strftime(char *buf, size_t maxsize, const char *format, const TDSDATEREC * dr, int prec)
{
	struct tm tm;

	size_t length;
	char *our_format;
	char *pz = NULL;
	bool z_found = false;
	
	assert(buf);
	assert(format);
	assert(dr);
	assert(0 <= dr->decimicrosecond && dr->decimicrosecond < 10000000);
	if (prec < 0 || prec > 7)
		prec = 3;

	tm.tm_sec = dr->second;
	tm.tm_min = dr->minute;
	tm.tm_hour = dr->hour;
	tm.tm_mday = dr->day;
	tm.tm_mon = dr->month;
	tm.tm_year = dr->year - 1900;
	tm.tm_wday = dr->weekday;
	tm.tm_yday = dr->dayofyear;
	tm.tm_isdst = 0;
#ifdef HAVE_STRUCT_TM_TM_ZONE
	tm.tm_zone = NULL;
#elif defined(HAVE_STRUCT_TM___TM_ZONE)
	tm.__tm_zone = NULL;
#endif

	/* more characters are required because we replace %z with up to 7 digits */
	our_format = tds_new(char, strlen(format) + 1 + 5);
	if (!our_format)
		return 0;

	strcpy(our_format, format);

	for (pz = our_format; *pz; ) {
		if (*pz++ != '%')
			continue;

		switch (*pz) {
		case 0:
			continue;
		case '%':
			/* escaped, do not treat as format on next iteration */
			break;
		case 'e':
			/* not portable: day of month, single digit preceded by a blank */
			/* not supported on old Windows versions */
			two_digit(pz-1, dr->day);
			break;
		case 'l':
			/* not portable: 12-hour, single digit preceded by a blank */
			/* not supported on: SCO Unix, AIX, HP-UX, Windows
			 * supported on: *BSD, MacOS, Linux, Solaris */
			two_digit(pz-1, (dr->hour + 11u) % 12u + 1);
			break;
		case 'z':
			/*
			 * Look for "%z" in the format string.  If found, replace it with dr->milliseconds.
			 * For example, if milliseconds is 124, the format string
			 * "%b %d %Y %H:%M:%S.%z" would become
			 * "%b %d %Y %H:%M:%S.124".
			 */
			if (z_found)
				break;
			z_found = true;

			--pz;
			if (prec || pz <= our_format || pz[-1] != '.') {
				char buf[12];
				sprintf(buf, "%07d", dr->decimicrosecond);
				memcpy(pz, buf, prec);
				strcpy(pz + prec, format + (pz - our_format) + 2);
				pz += prec;
			} else {
				strcpy(pz - 1, format + (pz - our_format) + 2);
				pz--;
			}
			continue;
		}
		++pz;
	}

	length = strftime(buf, maxsize, our_format, &tm);

	free(our_format);

	return length;
}

#if 0
static TDS_UINT
utf16len(const utf16_t * s)
{
	const utf16_t *p = s;

	while (*p++)
		continue;
	return p - s;
}
#endif

#include "tds_willconvert.h"

/**
 * Test if a conversion is possible
 * @param srctype  source type
 * @param desttype destination type
 * @return 0 if not convertible
 */
unsigned char
tds_willconvert(int srctype, int desttype)
{
	TDS_TINYINT cat_from, cat_to;
	TDS_UINT yn;

	tdsdump_log(TDS_DBG_FUNC, "tds_willconvert(%d, %d)\n", srctype, desttype);

	/* they must be from 0 to 255 */
	if (((srctype|desttype) & ~0xff) != 0)
		return 0;

	cat_from = type2category[srctype];
	cat_to   = type2category[desttype];
	yn = category_conversion[cat_from];

	yn = (yn >> cat_to) & 1;

	tdsdump_log(TDS_DBG_FUNC, "tds_willconvert(%d, %d) returns %s\n",
		    srctype, desttype, yn? "yes":"no");
	return yn;
}

#if 0
select day(d) as day, datepart(dw, d) as weekday, datepart(week, d) as week, d as 'date' from #t order by d
day         weekday     week        date                                                   
----------- ----------- ----------- ----------
          1           5           1 2009-01-01 Thursday
          2           6           1 2009-01-02 Friday
          3           7           1 2009-01-03 Saturday
          4           1           2 2009-01-04 Sunday
          5           2           2 2009-01-05
          6           3           2 2009-01-06
          7           4           2 2009-01-07
          8           5           2 2009-01-08
          9           6           2 2009-01-09
         10           7           2 2009-01-10
         11           1           3 2009-01-11
         12           2           3 2009-01-12
         13           3           3 2009-01-13
         14           4           3 2009-01-14
         15           5           3 2009-01-15
         16           6           3 2009-01-16
         17           7           3 2009-01-17
         18           1           4 2009-01-18
         19           2           4 2009-01-19
         20           3           4 2009-01-20
         21           4           4 2009-01-21
         22           5           4 2009-01-22
         23           6           4 2009-01-23
         24           7           4 2009-01-24
         25           1           5 2009-01-25
         26           2           5 2009-01-26
         27           3           5 2009-01-27
         28           4           5 2009-01-28
         29           5           5 2009-01-29
         30           6           5 2009-01-30
         31           7           5 2009-01-31
#endif
/**
 * Convert from db date format to a structured date format
 * @param datetype source date type. SYBDATETIME or SYBDATETIME4
 * @param di       source date
 * @param dr       destination date
 * @return TDS_FAIL or TDS_SUCCESS
 */
TDSRET
tds_datecrack(TDS_INT datetype, const void *di, TDSDATEREC * dr)
{
	int dt_days;
	unsigned int dt_time;

	int years, months, days, ydays, wday, hours, mins, secs, dms, tzone = 0;
	int l, n, i, j;

	memset(dr, 0, sizeof(*dr));

	if (datetype == SYBMSDATE || datetype == SYBMSTIME 
	    || datetype == SYBMSDATETIME2 || datetype == SYBMSDATETIMEOFFSET) {
		const TDS_DATETIMEALL *dta = (const TDS_DATETIMEALL *) di;
		dt_days = (datetype == SYBMSTIME) ? 0 : dta->date;
		if (datetype == SYBMSDATE) {
			dms = 0;
			secs = 0;
			dt_time = 0;
		} else {
			dms = dta->time % 10000000u;
			dt_time = (unsigned int) (dta->time / 10000000u);
			secs = dt_time % 60;
			dt_time = dt_time / 60;
		}
		if (datetype == SYBMSDATETIMEOFFSET) {
			--dt_days;
			dt_time = dt_time + 1440 + dta->offset;
			dt_days += dt_time / 1440;
			dt_time %= 1440;
			tzone = dta->offset;
		}
	} else if (datetype == SYBDATETIME) {
		const TDS_DATETIME *dt = (const TDS_DATETIME *) di;
		dt_time = dt->dttime;
		dms = ((dt_time % 300) * 1000 + 150) / 300 * 10000u;
		dt_time = dt_time / 300;
		secs = dt_time % 60;
		dt_time = dt_time / 60;
		dt_days = dt->dtdays;
	} else if (datetype == SYBDATETIME4) {
		const TDS_DATETIME4 *dt4 = (const TDS_DATETIME4 *) di;
		secs = 0;
		dms = 0;
		dt_days = dt4->days;
		dt_time = dt4->minutes;
	} else if (datetype == SYBDATE) {
		dt_days = *((const TDS_DATE *) di);
		dms = 0;
		secs = 0;
		dt_time = 0;
	} else if (datetype == SYBTIME) {
		dt_time = *((const TDS_TIME *) di);
		dms = ((dt_time % 300) * 1000 + 150) / 300 * 10000u;
		dt_time = dt_time / 300;
		secs = dt_time % 60;
		dt_time = dt_time / 60;
		dt_days = 0;
	} else if (datetype == SYB5BIGTIME) {
		TDS_UINT8 bigtime = *((const TDS_BIGTIME *) di);
		dt_days = 0;
		dms = bigtime % 1000000u * 10u;
		dt_time = (bigtime / 1000000u) % 86400u;
		secs = dt_time % 60;
		dt_time = dt_time / 60u;
	} else if (datetype == SYB5BIGDATETIME) {
		TDS_UINT8 bigdatetime = *((const TDS_BIGDATETIME*) di);
		dms = bigdatetime % 1000000u * 10u;
		bigdatetime /= 1000000u;
		secs = bigdatetime % 60u;
		bigdatetime /= 60u;
		dt_time = bigdatetime % (24u*60u);
		dt_days = bigdatetime / (24u*60u) - BIGDATETIME_BIAS;
	} else {
		return TDS_FAIL;
	}

	/*
	 * -53690 is minimun  (1753-1-1) (Gregorian calendar start in 1732) 
	 * 2958463 is maximun (9999-12-31)
	 */
	l = dt_days + (146038 + 146097*4);
	wday = (l + 4) % 7;
	n = (4 * l) / 146097;	/* n century */
	l = l - (146097 * n + 3) / 4;	/* days from xx00-02-28 (y-m-d) */
	i = (4000 * (l + 1)) / 1461001;	/* years from xx00-02-28 */
	l = l - (1461 * i) / 4;	/* year days from xx00-02-28 */
	ydays = l >= 306 ? l - 305 : l + 60;
	l += 31;
	j = (80 * l) / 2447;
	days = l - (2447 * j) / 80;
	l = j / 11;
	months = j + 1 - 12 * l;
	years = 100 * (n - 1) + i + l;
	if (l == 0 && (years & 3) == 0 && (years % 100 != 0 || years % 400 == 0))
		++ydays;

	hours = dt_time / 60;
	mins = dt_time % 60;

	dr->year = years;
	dr->month = months;
	dr->quarter = months / 3;
	dr->day = days;
	dr->dayofyear = ydays;
	dr->weekday = wday;
	dr->hour = hours;
	dr->minute = mins;
	dr->second = secs;
	dr->decimicrosecond = dms;
	dr->timezone = tzone;
	return TDS_SUCCESS;
}

/**
 * \brief convert a number in string to TDS_INT
 *
 * \return TDS_CONVERT_* or failure code on error
 * \remarks Sybase's char->int conversion tolerates embedded blanks, 
 * such that "convert( int, ' - 13 ' )" works.  
 * If we find blanks, we copy the string to a temporary buffer, 
 * skipping the blanks.  
 * We return the results of atoi() with a clean string.  
 * 
 * n.b. it is possible to embed all sorts of non-printable characters, but we
 * only check for spaces.  at this time, no one on the project has tested anything else.  
 */
static TDS_INT
string_to_int(const char *buf, const char *pend, TDS_INT * res)
{
	bool negative;
	unsigned int num;	/* we use unsigned here for best overflow check */
	size_t digits, decimals;

	buf = parse_numeric(buf, pend, &negative, &digits, &decimals);
	if (!buf)
		return TDS_CONVERT_SYNTAX;

	num = 0;
	for (; digits; --digits, ++buf) {
		/* add a digit to number and check for overflow */
		/* NOTE I didn't forget a digit, I check overflow before multiply to prevent overflow */
		if (num > 214748364u)
			return TDS_CONVERT_OVERFLOW;
		num = num * 10u + (*buf - '0');
	}

	/* check for overflow and convert unsigned to signed */
	if (negative) {
		if (num > 2147483648u)
			return TDS_CONVERT_OVERFLOW;
		*res = 0 - num;
	} else {
		if (num >= 2147483648u)
			return TDS_CONVERT_OVERFLOW;
		*res = num;
	}

	return sizeof(TDS_INT);
}

/**
 * \brief convert a number in string to TDS_INT8
 *
 * \return TDS_CONVERT_* or failure code on error
 */
static TDS_INT	/* copied from string_ti_int and modified */
parse_int8(const char *buf, const char *pend, TDS_UINT8 * res, bool * p_negative)
{
	TDS_UINT8 num;
	size_t digits, decimals;

	buf = parse_numeric(buf, pend, p_negative, &digits, &decimals);
	if (!buf)
		return TDS_CONVERT_SYNTAX;

	num = 0;
	for (; digits; --digits, ++buf) {
		/* add a digit to number and check for overflow */
		TDS_UINT8 prev = num;
		if (num > (((TDS_UINT8) 1u) << 63) / 5u)
			return TDS_CONVERT_OVERFLOW;
		num = num * 10u + (*buf - '0');
		if (num < prev)
			return TDS_CONVERT_OVERFLOW;
	}

	*res = num;
	return sizeof(TDS_INT8);
}

/**
 * \brief convert a number in string to TDS_INT8
 *
 * \return TDS_CONVERT_* or failure code on error
 */
static TDS_INT	/* copied from string_ti_int and modified */
string_to_int8(const char *buf, const char *pend, TDS_INT8 * res)
{
	TDS_UINT8 num;
	TDS_INT parse_res;
	bool negative;

	parse_res = parse_int8(buf, pend, &num, &negative);
	if (parse_res < 0)
		return parse_res;

	/* check for overflow and convert unsigned to signed */
	if (negative) {
		if (num > (((TDS_UINT8) 1) << 63))
			return TDS_CONVERT_OVERFLOW;
		*res = 0 - num;
	} else {
		if (num >= (((TDS_UINT8) 1) << 63))
			return TDS_CONVERT_OVERFLOW;
		*res = num;
	}
	return sizeof(TDS_INT8);
}

/**
 * \brief convert a number in string to TDS_UINT8
 *
 * \return TDS_CONVERT_* or failure code on error
 */
static TDS_INT	/* copied from string_to_int8 and modified */
string_to_uint8(const char *buf, const char *pend, TDS_UINT8 * res)
{
	TDS_UINT8 num;
	TDS_INT parse_res;
	bool negative;

	parse_res = parse_int8(buf, pend, &num, &negative);
	if (parse_res < 0)
		return parse_res;

	/* check for overflow */
	if (negative && num)
		return TDS_CONVERT_OVERFLOW;

	*res = num;
	return sizeof(TDS_UINT8);
}

/**
 * Parse a string for numbers.
 *
 * Syntax can be something like " *[+-] *[0-9]*\.[0-9]* *".
 *
 * The function ignore all spaces. It strips leading zeroes which could
 * possibly lead to overflow.
 * The function returns a pointer to the integer part followed by *p_digits
 * digits followed by a dot followed by *p_decimals digits (dot and
 * fractional digits are optional, in this case *p_decimals is 0).
 *
 * @param buf         start of string
 * @param pend        pointer to string end
 * @param p_negative  store if number is negative
 * @param p_digits    store number of integer digits
 * @param p_decimals  store number of fractional digits
 * @return pointer to first not zero digit. If NULL this indicate a syntax
 *         error.
 */
static const char *
parse_numeric(const char *buf, const char *pend, bool *p_negative, size_t *p_digits, size_t *p_decimals)
{
	enum { blank = ' ' };
#define SKIP_IF(cond) while (p != pend && (cond)) ++p;
	const char *p, *start;
	bool negative = false;

	*p_decimals = 0;
	p = buf;

	/* ignore leading spaces */
	SKIP_IF(*p == blank);
	if (p == pend) {
		*p_negative = false;
		*p_digits = 0;
		return p;
	}

	/* check for sign */
	switch (*p) {
	case '-':
		negative = true;
		/* fall thru */
	case '+':
		/* skip spaces between sign and number */
		++p;
		SKIP_IF(*p == blank);
		break;
	}
	*p_negative = negative;

	/* a digit must be present */
	if (p == pend)
		return NULL;

	/*
	 * skip leading zeroes
	 * Not skipping them cause numbers like "000000000000" to
	 * appear like overflow
	 */
	SKIP_IF(*p == '0');

	start = p;
	SKIP_IF(TDS_ISDIGIT(*p));
	*p_digits = p - start;

	/* parse decimal part */
	if (p != pend && *p == '.') {
		const char *decimals_start = ++p;
		SKIP_IF(TDS_ISDIGIT(*p));
		*p_decimals = p - decimals_start;
	}

	/* check for trailing spaces */
	SKIP_IF(*p == blank);
	if (p != pend)
		return NULL;

	return start;
}

static TDS_INT
string_to_float(const TDS_CHAR * src, TDS_UINT srclen, int desttype, CONV_RESULT * cr)
{
	char tmpstr[128];
	char *end;
	double res;

	/* ignore leading spaces */
	while (srclen > 0 && src[0] == ' ')
		++src, --srclen;

	/* ignore trailing blanks and nulls */
	while (srclen > 0 && (src[srclen - 1] == ' ' || src[srclen - 1] == '\0'))
		--srclen;

	if (srclen >= sizeof(tmpstr))
		return TDS_CONVERT_OVERFLOW;

	memcpy(tmpstr, src, srclen);
	tmpstr[srclen] = 0;

	errno = 0;
	res = strtod(tmpstr, &end);
	if (errno == ERANGE)
		return TDS_CONVERT_OVERFLOW;
	if (end != tmpstr + srclen)
		return TDS_CONVERT_SYNTAX;

	if (desttype == SYBREAL) {
		/* FIXME check overflows */
		cr->r = (TDS_REAL)res;
		return sizeof(TDS_REAL);
	}
	cr->f = res;
	return sizeof(TDS_FLOAT);
}

/** @} */
